JP2020038451A - Processing simulation device and machine-tool - Google Patents

Abstract

To provide a processing simulation device and a machin-tool for adequately simulating a shape of a workpiece after a cutting process with an annular tool that has an annular cutting edge, the edge having its own outer peripheral face as a rake face.SOLUTION: A processing simulation device comprises: an input part 210 inputting conditions about an annular tool which has an annular cutting-edge with an outer peripheral face as a rake face, a workpiece and a cutting process; a tool model formation part 221 forming a tool model; a workpiece model formation part 222 forming a workpiece model; a storage part 230 storing the tool model and the workpiece model; a model calculation part calculating a position and an attitude of the tool model and the workpiece model; and a cutting point calculation part 244 which simulates a shape of the workpiece after the cutting process by calculating cut points at which the workpiece is cut with the annular tool based on calculation results of the model calculation part.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a processing simulation device and a machine tool.

  Patent Literature 1 describes a technique of performing cutting on a workpiece while rotating a cutting tool (annular tool) having an annular cutting edge having an outer peripheral surface as a rake face. In the cutting using the cutting tool, the cutting is performed while rotating the cutting tool, thereby dispersing the cutting heat generated in the cutting edge over the entire outer peripheral surface, thereby improving the tool life.

JP 2016-26894 A

  In the technique described in Patent Document 1, cutting is performed while rotating the cutting tool in a state where the axis of the cutting tool is arranged non-parallel to the feed direction of the cutting tool with respect to the workpiece. In this case, there are many factors predicted to affect the machining accuracy, and it is difficult to easily optimize the conditions in the cutting process. Therefore, when performing the cutting in the above-described mode, there is a demand for optimizing the conditions by simulating the shape of the workpiece after performing the cutting under an arbitrarily set condition. .

  An object of the present invention is to provide a machining simulation device and a machine tool capable of accurately simulating the shape of a workpiece after cutting using an annular tool having an annular cutting edge having a rake face as an outer peripheral surface. I do.

  The machining simulation device of the present invention simulates the shape of a workpiece obtained by cutting while rotating an annular tool having an annular cutting edge having an outer peripheral surface as a rake face around an axis non-parallel to the feed direction. . The machining simulation device includes an input unit configured to input a condition related to the annular tool, the workpiece, and the cutting process, and a tool model that forms a tool model that approximates the shape of the annular tool based on the condition related to the annular tool. A forming unit, a workpiece model forming unit that forms a workpiece model that approximates the shape of the workpiece based on a condition relating to the workpiece, a storage unit that stores the tool model and the workpiece model, and the cutting. A model calculation unit for calculating the positions and orientations of the tool model and the workpiece model based on a condition related to processing; and a cutting operation at which the annular tool cuts the workpiece based on a calculation result of the model calculation unit. A cutting point calculation unit that simulates the shape of the workpiece after cutting by calculating points. The input unit is configured to input a displacement set value that causes the cutting edge to be displaced in a direction different from a feed direction of the annular tool with the rotation of the annular tool when the workpiece is cut by the annular tool. It is possible, the model calculation unit, based on the displacement set value, sequentially updates the position and orientation of the tool model displaced with the rotation of the annular tool, the cutting point calculation unit, the position and orientation, The cutting point is sequentially calculated using the updated tool model.

  Further, the machine tool of the present invention includes the above-described machining simulation device of the present invention, a tool spindle that rotatably supports the annular tool around an axis, a workpiece holding device that supports the workpiece, and An operation panel that can be input and a control device that controls the position and orientation of the annular tool and the workpiece based on the condition input to the operation panel.

  According to the processing simulation device and the machine tool of the present invention, the model calculation unit calculates the positions and postures of the tool model and the workpiece model based on the conditions input to the input unit, and the cutting point calculation unit includes the model calculation unit By calculating the cutting point based on the calculation result, the shape of the workpiece after cutting is simulated.

  In the machining simulation device, the input unit can input a displacement set value that causes the cutting edge to be displaced in a direction different from the feed direction of the annular tool with the rotation of the annular tool. Based on the displacement set value, the position and orientation of the tool model displaced with the rotation of the annular tool are sequentially updated. Then, the cutting point calculation unit sequentially calculates the cutting points using the tool model whose position and orientation have been updated. Accordingly, the machining simulation apparatus can make the shape of the workpiece model obtained as a result of the machining simulation approximate to the shape of the workpiece after the actual cutting.

  As a result, the machining simulation device can accurately simulate the shape of the workpiece after the cutting when performing the cutting using the annular tool. Then, the user using the processing simulation device can easily optimize the conditions set when actually performing the cutting based on the result of the processing simulation.

  Further, according to the machine tool of the present invention, the user can input the condition determined to be optimal to the operation panel based on the result of the processing simulation. Therefore, the machine tool can improve the processing accuracy of the workpiece.

It is a top view showing the whole composition of the cutting device used for the cutting method in one embodiment of the present invention. It is sectional drawing of the cutting device in the IB-IB line | wire of FIG. 1A. FIG. 4 is an enlarged view of the annular tool and the workpiece held by the tool holding device, showing a state in which the cutting edge of the annular tool is in contact with the workpiece. It is a block diagram of a control device. It is a block diagram of a processing simulation device. FIG. 3 is a diagram illustrating a state where input items of an input unit 210 are displayed on a display device. It is the figure which looked at a tool model and a work model from the X-axis direction. It is the figure which looked at the tool model and the work model from the Z-axis direction. FIG. 3 is a diagram partially showing a cross-sectional shape of a workpiece model viewed from an axial direction of the workpiece model; It is a figure explaining the processing which a cutting point calculation part performs. FIG. 9 is a diagram illustrating a part of the workpiece model after performing the process illustrated in FIG. 8 a plurality of times. FIG. 10 is a diagram illustrating a part of the workpiece model after the processing illustrated in FIG. 8 is further performed a plurality of times from the state illustrated in FIG. 9. It is a flowchart which shows the processing simulation process performed by a processing simulation apparatus. It is an example of the analysis result displayed on the display device, and shows the roundness of the workpiece model as the analysis result. It is an example of the analysis result displayed on the display device, and shows the roundness of the workpiece model as the analysis result. It is an example of the analysis result displayed on the display device, and shows a graph representing the relationship between the workpiece rotation speed and the roundness as the analysis result.

  Hereinafter, embodiments to which a processing simulation device and a machine tool according to the present invention are applied will be described with reference to the drawings. First, the configuration of the machine tool 1 according to an embodiment of the present invention will be described with reference to FIG.

(1. Overall configuration of machine tool 1)
As shown in FIG. 1, the machine tool 1 is a four-axis machining center including three mutually orthogonal axes (X axis, Y axis, and Z axis) and one rotation axis (C axis). The machine tool 1 mainly includes a workpiece holding device 10, a workpiece feeding device 20, a tool holding device 30, a control device 100, and a machining simulation device 200.

  The work holding device 10 rotatably holds the work W. The workpiece holding device 10 includes a headstock 11 and a tailstock 12. The headstock 11 rotatably supports one end (the right side in FIG. 1A) of the workpiece W in the axial direction. The headstock 11 includes a headstock body 13 as a housing, a rotating spindle 14 rotatably supported by the headstock body 13, and a rotating spindle motor 15 for applying a driving force for rotating the rotating spindle 14. Prepare. The tailstock 12 includes a tailstock body 16 as a housing, and a tailstock center 17 that rotatably supports the other end of the workpiece W in the axial direction (the left side in FIG. 1A).

  The workpiece holding device 10 supports both ends of the workpiece W in the direction of the axis Aw with the rotating main shaft 14 and the tailstock center 17 with the axis Aw of the workpiece W oriented parallel to the X-axis direction. Then, the workpiece W is rotated around the axis Aw by the drive of the rotary spindle motor 15.

  The workpiece feeder 20 sends the workpiece W in the X-axis direction. The workpiece feed device 20 includes a feed table 21 and an X-axis drive device 22 (see FIG. 3). 1A and 1B, the illustration of the X-axis driving device 22 is omitted. The feed stand 21 is provided so that the upper surface of the bed 2 can be moved in the X-axis direction. Specifically, a pair of X-axis guide rails 23 extending in the X-axis direction are provided on the upper surface of the bed 2, and the feed base 21 moves in the X-axis direction while being guided by the X-axis guide rails 23. The X-axis drive device 22 is a screw feed device that feeds the feed bar 21 in the X-axis direction (the direction of the axis Aw of the workpiece W) with respect to the bed 2.

  The headstock 11 and the tailstock 12 are installed on the upper surface of the feed stand 21, and the workpiece W supported by the headstock 11 and the tailstock 12 drives the X-axis driving device 22 to move the feed stand 21. By moving in the X-axis direction, the workpiece W is sent in the direction of the axis Aw of the workpiece W.

  The tool holding device 30 rotatably holds an annular tool 50 described later. The tool holding device 30 includes a column 31, a Z-axis drive device 32 (see FIG. 3), a saddle 33, a Y-axis drive device 34 (see FIG. 3), a tool spindle 35, and a tool spindle motor 36 (FIG. 3). Reference). 1A and 1B, illustration of the Z-axis driving device 32 and the Y-axis driving device 34 is omitted.

  The column 31 is provided so that the upper surface of the bed 2 can be moved in the Z-axis direction. Specifically, a pair of Z-axis guide rails 37 extending in the Z-axis direction are provided on the upper surface of the bed 2, and the column 31 is installed movably in the Z-axis direction while being guided by the Z-axis guide rails 37. . The Z-axis drive device 32 is a screw feed device that sends the column 31 to the bed 2 in the Z-axis direction.

  The saddle 33 is provided so that the side surface of the column 31 can be moved in the Y-axis direction. Specifically, a pair of Y-axis guide rails 38 extending in the Y-axis direction (vertical direction) are provided on the side surface of the column 31, and the saddle 33 can move in the Y-axis direction while being guided by the Y-axis guide rails 38. Placed in The Y-axis drive device 34 is a screw feed device that sends the saddle 33 in the Y-axis direction.

  The tool spindle 35 is supported by the saddle 33 so as to be rotatable around an axis parallel to the Z-axis direction. The tool spindle motor 36 is a motor that applies a driving force for rotating the tool spindle 35, and is housed inside the saddle 33. An annular tool 50 used for machining the workpiece W is detachably attached to the tip of the tool spindle 35. The annular tool 50 is rotatably held by the tool holding device 30, and moves in parallel with the bed 2 in the Z-axis direction and the Y-axis direction (a direction orthogonal to the feed direction) with the movement of the column 31 and the saddle 33. .

  Here, the annular tool 50 will be described with reference to FIG. As shown in FIG. 2, the annular tool 50 includes a tool main body 51 and a tool shaft 52. The tool main body 51 is a part for cutting the workpiece W, and is made of CBN. The tool body 51 is formed in a truncated cone shape, and the outer peripheral surface 53 of the tool body 51 forms a rake face. The end surface 54 on the large diameter side of the tool body 51 is formed as a flat flank, and the ridge formed by the outer peripheral surface 53 and the end surface 54 has a continuous circular shape, that is, an annular cut which is not divided in the middle. It is formed as a blade 55. The tool shaft portion 52 is a columnar portion extending from the end surface on the small diameter side of the tool main body 51, and is mounted on the tool spindle 35. The axis At of the annular tool 50 is provided coaxially with the tool spindle 35, and the annular tool 50 rotates around the axis At with the rotation of the tool spindle 35.

  As shown in FIG. 3, the control device 100 includes a workpiece rotation control unit 110, a tool rotation control unit 120, a feed control unit 130, and a displacement control unit 140. The workpiece rotation control unit 110 controls the drive of the rotary spindle motor 15 to rotate the workpiece W supported by the rotary spindle 14 and the tailstock center 17. The tool rotation control unit 120 controls the driving of the tool spindle motor 36 to rotate the annular tool 50 mounted on the tool spindle 35. The feed control unit 130 controls the driving of the X-axis driving device 22 and sends the workpiece W held by the workpiece holding device 10 in the X-axis direction by moving the feed table 21 in the X-axis direction. The displacement control unit 140 controls the driving of the Y-axis driving device 34 and the Z-axis driving device 32, and translates the annular tool 50 mounted on the tool holding device 30 in the Y-axis direction and the Z-axis direction.

  Note that the machine tool 1 is provided with an operation panel 3 capable of inputting conditions necessary for performing cutting. In the operation panel 3, it is possible to input conditions relating to the annular tool 50, the workpiece W, and the cutting. Then, the control device 100 performs control relating to the position and orientation of the annular tool 50 and the workpiece W and control relating to cutting based on the conditions input to the operation panel 3.

  The processing simulation device 200 simulates the shape of the workpiece W after cutting obtained when cutting is performed under set conditions. The user of the processing simulation apparatus 200 arbitrarily sets conditions necessary for performing the processing simulation, and evaluates the set conditions based on a simulation result obtained by the processing simulation performed under the set conditions. Can be. Then, the user performs a machining simulation while changing the conditions to be set, and compares and examines a plurality of obtained machining simulation results to optimize the conditions to be set when actually performing the cutting. it can. The details of the processing simulation device 200 will be described later.

(2. Cutting method)
Next, a method of cutting the workpiece W using the machine tool 1 will be described. As shown in FIGS. 1A and 1B, the tool holding device 30 arranges the axis At of the annular tool 50 non-parallel to the feed direction (X-axis direction) of the annular tool 50 to the workpiece W. Then, the machine tool 1 rotates the annular tool 50 about the axis At while rotating the workpiece W about the axis Aw, and sends the workpiece W in the X-axis direction.

  At this time, as shown in FIG. 2, the machine tool 1 moves the cutting edge 55 to the workpiece W with a predetermined gap (relief angle θ) provided between the end face 54 of the tool body 51 and the workpiece W. Contact. Thereby, the workpiece W is cut by the cutting edge 55.

(3. Processing simulation device 200)
Next, details of the processing simulation device 200 will be described with reference to FIGS. As shown in FIG. 4, the processing simulation device 200 mainly includes an input unit 210, a model forming unit 220, a storage unit 230, a calculation unit 240, an analysis unit 250, and an output unit 260.

(3-1: Input unit 210)
A user who uses the processing simulation apparatus 200 inputs conditions necessary for the processing simulation to the input unit 210. The processing simulation device 200 is provided with an input device 201 such as a keyboard, and the user uses the input device 201 to input conditions to the input unit 210. The processing simulation device 200 is provided with a display device 202 such as an LCD. The display device 202 has conditions that can be input to the input unit 210 and contents input to the input unit 210 via the input device 201. Is displayed.

  The input unit 210 includes a tool condition input unit 211 having conditions relating to the annular tool 50 as input items, a workpiece condition input unit 212 having conditions relating to the workpiece W as input items, and machining having conditions relating to cutting as input items. A condition input unit 213 is mainly provided.

  For example, as shown in FIG. 5, the input items of the tool condition input unit 211 include dimension values of the “tool diameter” of the annular tool 50 (that is, the outer diameter of the cutting edge 55) and the “tool clearance angle”. . When processing a cylindrical workpiece W, as input items of the workpiece condition input unit 212, dimension values of “outer diameter”, “inner diameter”, and “taper angle” of the workpiece W, and “processing” “Part” (for example, an outer peripheral surface or an inner peripheral surface). The input items of the processing condition input unit 213 include “tool rotation speed”, “workpiece rotation speed”, “feed speed”, “cut amount”, “machining position”, “tool posture”, and “tool runout”. Is included.

(3-2: Model Forming Unit 220)
As shown in FIG. 4, the model forming unit 220 includes a tool model forming unit 221 that forms a tool model Tm, and a work model forming unit 222 that forms a work model Wm. The tool model Tm is a model that approximates the shape of the tool body 51 of the annular tool 50 and is formed based on the dimension value input to the tool condition input unit 211. The workpiece model Wm is a model that approximates the shape of the workpiece W, and is formed based on the dimension value input to the workpiece condition input unit 212.

  As shown in FIG. 6A, the tool model Tm viewed from the X-axis direction is represented by a circle approximating the shape of the cutting edge 55. Note that the axis At of the tool model Tm shown in FIG. 6A is inclined with respect to the X axis when viewed from the Y-axis direction, and the upper end of the tool model Tm is located closer to the tool model Tm than the lower end of the tool model Tm. Is located on the relative feed direction side (upper side in FIG. 6A). As a result, the shape of the tool model Tm viewed from the X-axis direction is represented by an ellipse.

  As shown in FIG. 6B, the cross-sectional shape of the tool model Tm viewed from the direction of the axis Aw of the workpiece W is represented by a line segment approximating the shape of the end face 54 (see FIG. 2). And both ends of the tool model Tm represented by the line segment represent the position of the cutting edge 55.

  FIG. 6B shows a tool model Tm when “0” is input as a dimension value of “tool clearance angle” which is one of the input items included in the tool condition input unit 211. The model Tm is represented by a straight line. On the other hand, when “0” is input as the dimension value of the “tool clearance angle”, the tool model Tm generates the end face 54 having the tool clearance angle based on the set value input to the “tool clearance angle”. It is represented by a cross-sectional shape.

(3-3: Storage Unit 230)
The storage unit 230 includes a tool model storage unit 231, a workpiece model storage unit 232, a condition storage unit 233, and a calculation result storage unit 234. The tool model storage unit 231 stores the tool model Tm formed by the tool model forming unit 221. The workpiece model storage unit 232 stores the workpiece model Wm formed by the workpiece model forming unit 222. In addition, the workpiece model storage unit 232 sequentially updates the workpiece model Wm that changes with the progress of the cutting process during the execution of the machining simulation.

  The condition storage unit 233 stores dimension values and set values input as conditions to the tool condition input unit 211, the workpiece condition input unit 212, and the processing condition input unit 213. After the machining simulation ends, the calculation result accumulation unit 234 stores the workpiece model Wm after the cutting process stored in the workpiece model storage unit 232 as a machining simulation result. In addition, the calculation result storage unit 234 stores the dimension value and the set value stored in the condition storage unit 233 in association with the processing simulation result.

(3-4: arithmetic unit 240)
The calculation unit 240 includes a model calculation unit 243 having a tool model calculation unit 241 and a workpiece model calculation unit 242, and a cutting point calculation unit 244. The tool model calculation unit 241 calculates the position and orientation of the tool model Tm during cutting based on the set values input to the processing condition input unit 213.

(3-4-1: Tool model calculation unit 241)
Specifically, the tool model calculation unit 241 determines the reference of the tool model Tm at the time of cutting based on the set values of “machining position” and “tool posture” which are one of the input items included in the processing condition input unit 213. Calculate the position.

  Here, the “machining position” is a reference position in the circumferential direction of the annular tool 50 as viewed from the direction of the axis Aw of the workpiece W, and the cutting edge closest to the axis Aw of the workpiece W. 55 position. Of the two ends of the tool model Tm shown in FIG. 6B, an end 55m located at a position close to the axis Aw of the workpiece W is the most to the axis Aw of the workpiece W among the cutting edges 55 provided in an annular shape. The figure shows a part at a near position, and the reference position of the end 55m is set based on the set value of the "machining position".

  Specifically, the “machining position” is a line parallel to the X-axis, and the circumferential direction of the end 55m based on a state where the end 55m is on a line passing through the axis Aw of the workpiece W. Is an item for inputting the amount of deviation in as a set value.

  Specifically, when "0" is input as the set value in the "machining position", the end portion 55m is arranged on a line parallel to the X axis passing through the axis Aw of the workpiece W. On the other hand, when a positive value is input as the set value of the “machining position”, the end 55m is shifted clockwise around the axis Aw of the workpiece W from the state where the set value is “0”. Placed in When a negative value is input as the set value of the “machining position”, the end portion 55m is shifted from the state where the set value is “0” to a position shifted counterclockwise around the axis Aw of the workpiece W. Be placed.

  Note that the distance between the axis Aw of the workpiece W and the end 55 m is input to the setting value of “cut amount” which is one of the input items of the processing condition input unit 213 and the workpiece condition input unit 212. It is determined based on the dimensional value and the “machining part”.

  The “tool posture” is the direction of the axis At of the annular tool 50. Specifically, “B axis” is an item for inputting the amount of inclination of the axis line At of the annular tool 50 with respect to the X axis when viewed from the Y axis direction (from left to right in FIG. 6A). For example, when a positive value is input as a set value for the input item of “B axis”, the axis line At of the annular tool 50 tilts clockwise as viewed from the Y axis direction. On the other hand, when a negative value is input as the set value of “B axis”, the axis line At of the annular tool 50 is inclined counterclockwise as viewed from the Y axis direction. In the example shown in FIGS. 6A and 6B, a negative value is input as the set value of “B axis”.

  The “C-axis” of the “tool posture” is an item for inputting the inclination of the axis At of the annular tool 50 with respect to the X-axis when viewed from the Z-axis direction (from the lower side to the upper side shown in FIG. 6A). For example, when a positive value is input as a set value for the input item of “C-axis”, the axis line At of the annular tool 50 is inclined clockwise as viewed from the Z-axis direction, and is set as the set value of “C-axis”. When a negative value is input, the axis line At of the annular tool 50 tilts counterclockwise as viewed from the Z-axis direction. In the example shown in FIGS. 6A and 6B, “0” is input in the input item of “C axis”.

  Further, the tool model calculation unit 241 calculates the displacement amount of the end 55m with respect to the reference position based on the set value of “tool runout” which is one of the input items included in the processing condition input unit 213. The “tool runout” refers to the runout amount of the annular tool 50 that is predicted to occur at the time of cutting, and the set value of “tool runout” is a predicted value of the runout amount of the annular tool 50. .

  Here, the tool run-out causes the cutting edge 55 to be displaced in a direction different from the feed direction of the annular tool 50 in the cutting performed while rotating the annular tool 50 around the axis At. The cause of the “tool runout” is, for example, that the axis At of the annular tool 50 is fixed in an inclined state with respect to the axis of the tool spindle 35 when the annular tool 50 is mounted on the tool spindle 35. Can be considered. That is, when the annular tool 50 is rotated by the tool spindle 35 in this state, the cutting position of the workpiece W by the cutting edge 55 (hereinafter referred to as “cutting point Cp”) fluctuates in the X-axis direction. This is reflected in the shape of the workpiece W after processing.

  In this regard, the processing condition input unit 213 is provided with “axial” as one of the input items of “tool runout”. “Axial” is an item for inputting the amount of deflection of the axis line At of the annular tool 50 with respect to the X axis. Then, the user inputs a predicted value of the shake in the X-axis direction as a set value in the “axial” input item. Accordingly, the tool model calculation unit 241 moves the end 55m in a direction perpendicular to the axis At of the annular tool 50 with respect to the reference position determined based on the set value of the “machining position” with the progress of the machining simulation. Can be displaced. As a result, when simulating the shape of the workpiece W after the cutting, the processing simulation apparatus 200 may reflect the effect of the runout caused by the mounting posture of the annular tool 50 on the tool spindle 35 in the result of the processing simulation. it can.

  Another cause of the “tool runout” is a cutting resistance applied to the cutting edge 55 during cutting. That is, when cutting resistance is applied to the cutting edge 55, the annular tool 50 swings in a direction orthogonal to the axis At of the annular tool 50. As a result, the cutting point Cp oscillates in a direction orthogonal to the axis line At, and the influence of the oscillation is reflected on the shape of the workpiece W after machining.

  In this regard, the machining condition input unit 213 is provided with “radial” as one of the input items of “tool runout”. The “radial” is an item for inputting a runout amount of the annular tool 50 in the direction of the axis At. Then, the user inputs a predicted value of the runout amount of the annular tool 50 in the direction of the axis line At as a set value in the “radial” input item. Accordingly, as the machining simulation proceeds, the cutting point Cp is displaced in the direction of the axis line At of the annular tool 50 with respect to the reference position determined based on the set value of the “machining position”. As a result, when simulating the shape of the workpiece W after cutting, the processing simulation apparatus 200 can reflect the influence of runout due to cutting resistance on the result of the processing simulation.

  Here, with respect to the input value of “rotational runout”, the user actually measures the rotational runout of the annular tool 50 in a state where the annular tool 50 is mounted on the tool spindle 35, and compares the measurement result with the “tool runout”. It may be input as a predicted value. Thereby, the user can make the shape of the workpiece W after cutting obtained as a result of the processing simulation by the processing simulation device 200 approximate to the shape of the workpiece W after actual cutting.

  As described above, the tool model calculation unit 241 calculates the position and the posture of the tool model Tm based on the set values of the “cut amount”, the “processing position”, and the “tool posture” input to the processing condition input unit 213. I do. Further, the tool model calculation unit 241 is configured to change the tool model that changes sequentially during the execution of the machining simulation based on the set values of “tool rotation speed”, “feed speed”, and “tool runout” input to the machining condition input unit 213. The position and orientation of Tm are calculated and updated.

  “Tool runout” is included as an input item. The set value input to the “tool runout” is a displacement set value that causes displacement of the annular tool 50 in the direction of the axis At and the direction orthogonal to the axis At with the rotation of the annular tool 50. Then, the tool model calculation unit 241 sequentially updates the position and orientation of the tool model Tm based on the displacement set value. Therefore, the processing simulation device 200 can make the operation of the tool model Tm during execution of the processing simulation closer to the operation of the annular tool 50 during actual cutting.

(3-4-2: Workpiece model calculation unit 242)
The workpiece model calculation unit 242 is configured to change the posture of the workpiece model Wm that changes sequentially during the execution of the machining simulation based on the set value of “workpiece rotation speed” which is one of the input items included in the machining condition input unit 213. Is calculated and updated.

  Here, as shown in FIG. 7, in the workpiece model Wm, a cross-sectional shape orthogonal to the axis Aw of the workpiece W is represented by a plurality of outer points Op. In addition, in order to simplify the drawing, in FIG. 7, except for a part, the cross-sectional shape of the workpiece W represented by a plurality of outer points Op is illustrated by a line. Each of the plurality of outer points Op is associated with angle information that sets one of the plurality of outer points Op as the reference outer point Opr.

  During the execution of the machining simulation, the workpiece model calculation unit 242 shifts each external point Op around the axis Aw of the workpiece model Wm based on the set value of the “workpiece rotation speed” input to the machining condition input unit 213. The amount of rotation to be moved is determined. Each of the plurality of outer points Op is connected to the axis Aw of the workpiece model Wm by a radius line L. Note that FIG. 7 shows only a part of the radius line L for simplification of the drawing.

(3-4-3: Cutting point calculation unit 244)
As illustrated in FIG. 8, the cutting point calculation unit 244 calculates the position of the cutting point Cp based on the position and orientation of the tool model Tm and the workpiece model Wm calculated by the model calculation unit 243. Specifically, the cutting point calculation unit 244 sets the position of the end 55m when the end 55m of the tool model Tm is arranged on the one radius line L as the cutting point Cp. Then, the cutting point calculation unit 244 performs a process of moving the outer shape point Op on the one radial line L to the cutting point Cp. The shape of the workpiece W after cutting is represented by the outer point Op moved by this processing.

  As shown in FIGS. 9 and 10, during the execution of the machining simulation, the tool model calculation unit 241 repeatedly updates the position and orientation of the tool models Tm and Wm, and the workpiece W and the annular tool 50 Simulate the rotation around the axes Aw and At. Then, the cutting point calculation unit 244 moves the outer shape point Op to the position of the cutting point Cp every time the end 55m is arranged on the radius line L. As described above, the calculation unit 240 sequentially performs the movement of the outer shape point Op and the update of the position and orientation of the tool model Tm and Wm, and gradually forms the shape of the work W after the work by the moved outer shape point Op. I will do it.

  Further, during the execution of the machining simulation, the model calculation unit 243 moves the tool model Tm relative to the workpiece model Wm in the Z-axis direction based on the set value of the “feed speed” input to the machining condition input unit 213. Send. Along with this, the processing simulation device 200 determines the shape of the workpiece model Wm after cutting for each of the cross-sectional shapes (see FIG. 6B) of the plurality of workpiece models Wm at different positions in the direction of the axis Aw of the workpiece model Wm. To simulate. As a result, the processing simulation apparatus 200 can simulate the shape of the workpiece W after the cutting process over the entirety of the workpiece W in the direction of the axis Aw.

  Then, when the machining simulation is completed, the cutting point calculation unit 244 stores the final data on the shape of the workpiece model Wm stored in the workpiece model storage unit 232 into the dimension values and the settings stored in the condition storage unit 233. The result is linked to the value and stored in the calculation result storage unit 234 as a processing simulation result.

(4. Processing simulation processing)
Next, a simulation process executed by the processing simulation device 200 will be described with reference to a flowchart shown in FIG.

  As shown in FIG. 11, the tool model forming unit 221 forms the tool model Tm based on the set value input to the tool condition input unit 211, and the workpiece model forming unit 222 transmits the tool model Tm to the workpiece condition input unit 212. A workpiece model Wm is formed based on the input set values (S1). Subsequently, the tool model forming unit 221 stores the formed tool model Tm in the tool model storage unit 231, and the workpiece model forming unit 222 stores the formed workpiece model Wm in the workpiece model storage unit 232 ( S2).

  Next, the tool model calculation unit 241 calculates the position and orientation of the tool model Tm based on the set values input to the processing condition input unit 213, and the workpiece model calculation unit 242 inputs the position and orientation to the processing condition input unit 213. The posture of the workpiece model Wm is calculated based on the set value (S3). Then, the cutting point calculation unit 244 calculates the position of the cutting point Cp based on the calculated position and orientation of the tool model Tm and the workpiece model Wm (S4). Then, the cutting point calculation unit 244 determines whether the obtained cutting point Cp is on the radius line L (S5).

  As a result, if the cutting point Cp is on the line of the radius line L (S5: Yes), the cutting point calculation unit 244 moves the external point Op on the same line of the radius line L as the cutting point Cp to the position of the cutting point Cp. The shape of the workpiece model Wm to be moved to is updated, and the updated workpiece model Wm is stored in the workpiece model storage unit 232 (S6). On the other hand, if the cutting point Cp is not on the line of the radius line L (S5: No), the cutting point calculation unit 244 skips the processing of S6.

  After the processing in S5 and S6, the tool model calculation unit 241 updates the position and orientation of the tool model Tm based on the set values input to the processing condition input unit 213, and the workpiece model calculation unit 242 determines The posture of the workpiece model Wm is updated based on the set value input to the unit 213 (S7). By the processing in S7, the tool model Tm and the workpiece model Wm rotate and move around the respective axes At and Aw, and the tool model Tm moves in parallel with the workpiece model Wm in the X-axis direction (relative feed). Is done.

  After the processing in S7, the cutting point calculation unit 244 determines whether or not the processing simulation has been completed (S8). For example, the cutting point calculation unit 244 determines that the machining simulation has ended when the relative feed to the workpiece model Wm has ended. If the machining simulation has not been completed (S8: No), the cutting point calculation unit 244 returns to the process of S4 and calculates the cutting point Cp. On the other hand, when the machining simulation is completed (S8: Yes), the cutting point calculation unit 244 stores the contents stored in the condition storage unit 233 and the workpiece model storage unit 232 as a simulation result in the calculation result storage unit 234 ( S9), this process ends.

(5: Analysis unit 250 and output unit 260)
Next, the analysis unit 250 and the output unit 260 will be described. The analysis unit 250 performs an analysis using the processing simulation result stored in the calculation result accumulation unit 234, and the output unit 260 outputs the content analyzed by the analysis unit 250 to the display device 202.

  The input unit 210 is provided with an analysis content input unit 214. The analysis unit 250 performs an analysis according to the analysis content input to the analysis content input unit 214 by the user. For example, the analysis content of the analysis unit 250 includes the roundness and surface roughness of the workpiece W. In addition, when displaying the analysis result by the analysis unit 250 on the display device 202, the output unit 260 displays the analysis result in a form based on the instruction input by the user to the analysis content input unit 214. For example, as a display mode of the analysis result used for one processing simulation result, a display of a cross-sectional shape of the workpiece model Wm, a 3D display of a surface roughness of the processing surface, a pattern of a pattern formed on the processing surface due to runout are provided. Display and the like are exemplified. Thus, the user can easily optimize the conditions set when actually performing the cutting.

  For example, FIG. 12A and FIG. 12B show the analysis results of the roundness. The analysis result of the roundness shown in FIG. 12A and the analysis result of the roundness shown in FIG. 12B are based on simulation results obtained by inputting different setting values to the processing condition input unit 213. The analysis result shown in FIG. 12B indicates that the roundness is smaller (closer to a perfect circle) than the analysis result shown in FIG. 12A. That is, the cutting performed using the set value used in the processing simulation result illustrated in FIG. 12B is more roundness of the workpiece W after the cutting than the cutting performed using the set value used in the processing simulation result illustrated in FIG. 12A. Can be reduced.

  Further, since the calculation result storage unit 234 can store a plurality of processing simulation results, the output unit 260 can display the plurality of processing simulation results side by side. In other words, the user can compare the respective simulation results stored in the calculation result storage unit 234 when performing the machining simulation a plurality of times while changing the set value.

  For example, in FIG. 13, while changing the set values of the “workpiece rotation speed” and the “feed speed” in the processing condition input unit 213, a plurality of settings are performed while keeping other set values such as the “tool rotation speed” constant. The analysis result of the roundness using the simulation result is shown. Specifically, FIG. 13 illustrates a state in which a graph indicating the relationship between the workpiece rotation speed and the roundness is displayed on the display device 202. The graph shown in FIG. 13 shows that when the set value of the “workpiece rotation speed” is b, the roundness is smaller than when the set value of the “workpiece rotation speed” is a or c. It is shown. Further, in the graph shown in FIG. 13, when the set value of the “feed speed” is Z, the roundness tends to be smaller than when the set value of the “feed speed” is X or Y. It shows that.

  As described above, the user performs the processing simulation while changing the setting conditions, and compares and examines a plurality of obtained processing simulation results, thereby optimizing the conditions to be set when actually performing the cutting processing. be able to

  As described above, the processing simulation device 200 includes the input unit 210 for inputting the annular tool 50, the workpiece W, and the conditions regarding the cutting. The conditions that can be input to the processing condition input unit 213 of the input unit 210 include “tool runout” as an input item. The set value input to the “tool runout” is a displacement set value that causes displacement of the annular tool 50 in the direction of the axis At and the direction orthogonal to the axis At with the rotation of the annular tool 50.

  The machining simulation device 200 includes a tool model forming unit 221 that forms a tool model Tm that approximates the shape of the annular tool 50 based on the conditions regarding the annular tool 50 input to the tool condition input unit 211. Further, the processing simulation device 200 includes a workpiece model forming unit 222 that forms a workpiece model Wm that approximates the shape of the workpiece W based on the condition relating to the workpiece W input to the workpiece condition input unit 212. Further, the processing simulation device 200 includes a storage unit 230 that stores the tool model Tm and the workpiece model Wm formed by the model forming unit 220.

  The processing simulation device 200 includes a model calculation unit 243, and the model calculation unit 243 calculates the positions and postures of the tool model Tm and the workpiece model Wm based on the cutting-related conditions input to the processing condition input unit 213. . Further, the processing simulation device 200 includes a cutting point calculation unit 244, and the cutting point calculation unit 244 determines a cutting point Cp at which the annular tool 50 cuts the workpiece W based on the calculation result of the model calculation unit 243. The calculation simulates the shape of the workpiece W after cutting.

  Furthermore, the model calculation unit 243 sequentially updates the position and orientation of the tool model Tm that is displaced with the rotation of the annular tool 50 based on the displacement set value. Then, the cutting point calculation unit 244 sequentially calculates the cutting point Cp using the tool model Tm whose position and orientation have been updated by the model calculation unit 243. Thereby, the processing simulation apparatus 200 can make the shape of the workpiece model Wm obtained as a result of the processing simulation close to the shape of the workpiece W after the actual cutting.

  As a result, when performing the cutting using the annular tool 50, the processing simulation device 200 can accurately simulate the shape of the workpiece W after the cutting. Then, the user using the processing simulation device 200 can easily optimize the conditions set when actually performing the cutting based on the result of the processing simulation.

  In addition, the machining condition input unit 213 includes the runout amount of the annular tool 50 in the direction of the axis At as the runout amount of the annular tool 50. Thereby, the processing simulation apparatus 200 can reflect the influence of the run-out of the annular tool 50 on the result of the processing simulation. Further, the machining condition input unit 213 includes, as the runout amount of the annular tool 50, the runout amount of the annular tool 50 in a direction orthogonal to the axis At. Thereby, the processing simulation apparatus 200 can reflect the influence of the run-out on the result of the processing simulation.

  As described above, since the input unit 210 includes the runout amount of the annular tool 50 as the displacement set value that can be input to the processing condition input unit 213, the processing simulation apparatus 200 determines whether or not the tool model Tm is being executed during the processing simulation. The operation can be approximated to the operation of the annular tool 50 during actual cutting.

  Further, the processing simulation device 200 uses the processing simulation result of the workpiece model Wm by the cutting point calculation unit 244 to analyze the shape of the workpiece W that has been cut under the conditions input to the input unit 210. Is provided. Thus, the user can easily optimize the conditions set when actually performing the cutting.

  Then, the analysis unit 250 performs an analysis on the roundness of the workpiece W. Therefore, the user can easily optimize the conditions when improving the roundness of the workpiece W. Similarly, the analysis unit 250 performs an analysis on the surface roughness of the workpiece W. Therefore, the user can easily optimize the conditions when improving the surface roughness of the workpiece W.

  Further, the user can input the condition determined to be optimal to the operation panel 3 based on the result of the processing simulation. Therefore, the machine tool 1 can improve the processing accuracy of the workpiece W.

(6. Others)
As described above, the present invention has been described based on the above embodiments. However, the present invention is not limited to the above embodiments, and it can be easily inferred that various modifications and improvements can be made without departing from the spirit of the present invention. Things.

  For example, in the above embodiment, the case where the workpiece W is cylindrical has been described as an example. However, even when the workpiece W other than the cylindrical workpiece is cut, the processing using the processing simulation device 200 is performed. A simulation can be performed. That is, the processing simulation device 200 can perform the processing simulation even when the workpiece W is a rotating body such as a cylinder or a cam, or when the workpiece W is a non-rotating body.

  In the above-described embodiment, a case has been described where the displacement set value that can be input to the input unit 210 is the runout amount of the annular tool 50. However, the input unit 210 can input a displacement set value other than the runout amount of the annular tool 50. May be included as a simple item. For example, the tool condition input unit 211 may include a set value relating to the loss of the cutting edge 55 as an inputtable displacement set value. In this case, the processing simulation device 200 can reflect the effect of the lack of the cutting edge 55 on the result of the processing simulation.

  1: machine tool, 3: operation panel, 10: workpiece holding device, 35: tool spindle, 50: annular tool, 53: outer peripheral surface, 55: cutting edge, 100: control device, 200: processing simulation device, 210: Input unit: 221: Tool model forming unit, 222: Workpiece model forming unit, 230: Storage unit, 243: Model calculating unit, 244: Cutting point calculating unit, 250: Analyzing unit, At: Axis of annular tool, Aw: Workpiece axis, Cp: Cutting point, Tm: Tool model, W: Workpiece, Wm: Workpiece model

Claims (9)

An annular tool having an annular cutting edge having a rake face on an outer peripheral surface, a machining simulation device that simulates a shape of a cut workpiece while rotating around an axis that is not parallel to a feed direction,
The annular tool, the workpiece, and an input unit for inputting conditions related to cutting.
A tool model forming unit that forms a tool model that approximates the shape of the annular tool, based on the condition regarding the annular tool,
A workpiece model forming unit that forms a workpiece model that approximates the shape of the workpiece based on the condition relating to the workpiece;
A storage unit that stores the tool model and the workpiece model,
A model calculation unit configured to calculate the position and orientation of the tool model and the workpiece model based on the conditions related to the cutting process;
A cutting point calculating unit that simulates the shape of the workpiece after cutting by calculating a cutting point that is a position at which the annular tool cuts the workpiece based on a calculation result of the model calculating unit;
With
The input unit is configured to input a displacement set value that causes the cutting edge to be displaced in a direction different from a feed direction of the annular tool with the rotation of the annular tool during cutting of the workpiece by the annular tool. Is possible,
The model calculation unit, based on the displacement set value, sequentially updates the position and orientation of the tool model that is displaced with the rotation of the annular tool,
The machining simulation device, wherein the cutting point calculation unit sequentially calculates the cutting points using the tool model whose position and orientation are updated.   The machining simulation device according to claim 1, wherein the displacement set value includes a runout amount of the annular tool.   The machining simulation device according to claim 2, wherein the displacement set value includes a runout amount of the annular tool in an axial direction.   The machining simulation device according to claim 2, wherein the displacement set value includes a runout amount in a direction orthogonal to an axis of the annular tool.   The processing simulation device according to any one of claims 1 to 4, wherein the displacement set value includes a set value related to a defect formed in the cutting edge.   The machining simulation device includes an analysis unit configured to analyze a shape of the workpiece that has been cut under the conditions input to the input unit, using a machining simulation result of the workpiece model by the cutting point calculation unit. The processing simulation apparatus according to any one of claims 1 to 5. The workpiece is a rotating body,
The machining simulation device according to claim 6, wherein the analysis unit performs an analysis on the roundness of the workpiece.   The machining simulation device according to claim 6, wherein the analysis unit performs an analysis on a surface roughness of the workpiece. A processing simulation device according to any one of claims 1 to 8,
A tool spindle that rotatably supports the annular tool around an axis,
A workpiece holding device for holding the workpiece,
An operation panel capable of inputting the condition,
A control device that controls the position and orientation of the annular tool and the workpiece based on the condition input to the operation panel,
A machine tool.

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